Autor: |
Klaassen van Oorschot B; Department of Physics, University of Puget Sound , Tacoma, Washington, USA., Bryson KA; Department of Physics, University of Puget Sound , Tacoma, Washington, USA., Danner O; Department of Physics, University of Puget Sound , Tacoma, Washington, USA., Eklof JF; Department of Physics, University of Puget Sound , Tacoma, Washington, USA., Lopez A; Department of Physics, University of Puget Sound , Tacoma, Washington, USA., Wah-Blumberg J; Department of Physics, University of Puget Sound , Tacoma, Washington, USA., Pepper RE; Department of Physics, University of Puget Sound , Tacoma, Washington, USA. |
Abstrakt: |
Splash-cup plants disperse propagules via raindrops striking cup-shaped fruiting bodies. The seeds are ejected at velocities up to five times the impact speed of the raindrop and are dispersed up to 1 m from the parent plant. Here, we examine the effects of cup angles and the presence of seed mimics to understand the dynamics of this unique method of dispersal. Our findings demonstrate that: (i) cup angles that launched seeds the furthest ranged from approximately 30° to 50°, matching the range of angles seen in splash-cup plants. (ii) Seeds travel shorter distances than water droplets alone, and this distance depends on the number of seeds in the cup. (iii) Not all seeds are ejected from initially dry cups, leaving cups with some seeds and some water. (iv) Nearly all seeds are ejected from cups that contain both water and seeds, and those that are ejected travel significantly further than those from dry cups. These results confirm the possibility that the conical shape of splash cup plants may be adapted to maximize dispersal distance and benefit from multiple splash events. Our results also illustrate that future work on these plants should include seeds rather than water droplets alone. |